Respirator with improved exhalation valve and control means



Dec. 23, 1969 F. M. BIRD ETAL RESPIRATOR WITH IMPROVED EXHALATION VALVE AND CONTROL MEANS 2 Sheets-Sheet 1 Filed Aug. 2, 1965 INVENTORS Forrest M. Bi 0 BY Henry I. Pohnaorf @7544 @QZQ Attorneys Dec. 23, 1969 F. M. BIRD ETAL RESPIRATOR WITH IMPROVED EXHALATION VALVE AND CONTROL MEANS Filed Aug. 2, 1965 III 2 Sheets-Sheet 2 I III INVENTORS Forrest M. Bird BY Henry L. Pohndor! Anorneys United States Patent 3,485,243 RESPIRATOR WITH IMPROVED EXHALATION VALVE AND CONTROL MEANS Forrest M. Bird, 212 NW. Cerritos Drive, Palm Springs, Calif. 92262, and Henry L. Pohndorf, 1227 Brewster Drive, El Cerrito, Calif. 94530 Filed Aug. 2, 1965, Ser. No. 476,508 Int. Cl. A621: 7/00; F04f /24; A61rn 16/00 US. Cl. 128145.8 13 Claims ABSTRACT OF THE DISCLOSURE Respirator having an exhalation valve and two control units and providing inhalation and exhalation phases of operation. The exhalation valve includes a venturi passage, nozzles and tubular members for entraining air flow to and from the airway of a patient.

This invention relates to a respirator and more particularly to a respirator particularly useful for infant resuscitation.

With respirators presently available, it has been found to be very diflicult to give mechanical assistance to an infant having hyaline membrane disease, obstructive lung disease or other breathing difficulties because the infant lungs are very small and the breathing rates required are very rapid. In addition, occasionally the pressure required to ventilate the small infant lung is much higher than that encountered in adults. There is, therefore, a need for a new and improved respirator which is particularly useful in ventilating infants.

In general, it is an object of the present invention to provide a respirator with which it is possible to ventilate infants.

Another object of the invention is to provide a respirator of the above character which can be recycled very rapidly.

Another object of the invention is to provide a respirator of the above character in which the entire respirator can be turned off with a single control.

Another object of the invention is to provide a respirator of the above character which includes a parallel booster which only operates during the inspiration phase.

Another object of the invention is to provide a respirator of the above character in which a separate independent gas flow can be delivered to the nebulizer.

Another object of the invention is to provide a respirator of the above character which incorporates a particularly unique exhalation valve.

Another object of the invention is to provide a respirator of the above character which includes a particularly unique control cartridge.

Additional objects and features of the invention will appear from the following description in which a preferred embodiment is set forth in detail in conjunction with the accompanying drawings.

Referring to the drawings:

FIGURE 1 is a diagram with certain of the parts schematically illustrated of a respirator incorporating the present invention.

FIGURE 2 is a cross sectional view of the control cartridge utilized as a part of the respirator shown in FIG- URE 1.

FIGURE 3 is a cross sectional view taken along the line 3-3 of FIGURE 2.

FIGURE 4 is a cross sectional view taken along the line 4--4 of FIGURE 2.

FIGURE 5 is an enlarged cross sectional view of the exhalation valve utilized in the respirator shown in FIG- URE 1.

3,485,243 Patented Dec. 23, 1969 As shown in the drawings, the respirator consists of a controller 11 of the type shown in United States letters Patent 3,191,596. As disclosed therein, such a controller includes an inlet 12 adapted to be connected to a source of gas under pressure and an outlet 13 adapted to be connected to the airway of the patient. Such a controller also includes a main control valve (not shown) in the controller movable between open and closed positions to control the flow of inhalant gas from the inlet to the outlet. Means is provided for operating the main control valve so that the main control valve is in an open position during the inhalation phase and in a closed position during the exhalation phase of the respirator. The means for operating the main control valve includes means for sensing when a predetermined pressure is reached in the outlet for shifting the main control valve from an open position to a closed position. Such a controller also includes a positive pressure outlet 16 and a negative pressure outlet 17.

The respirator also includes a control cartridge 21 which is adapted to be connected to the inlet of the controller 11 and which is also adapted to be connected to a source of gas under pressure 22. The respirator also includes an exhalation valve 23, a nebulizer 24, and a patient adapter 26. The nebulizer can be of the type described in copending application Ser. No. 447,852, filed Apr. 13, 1965, now Patent No. 3,353,536. As described in that application, the nebulizer includes an inlet 28 which, as shown in FIGURE 1, is mounted on the outlet 13 of the controller 11. It is also provided with an outlet 29 and an additional inlet 31.

The control cartridge 21 consists of a cylindrical body 36 which is provided with a large, centrally disposed bore extending longitudinally of the body. The bore 37 opens into a large cylindrical recess 38 at one end of the body 36 as shown in FIGURE 2. The large bore 37 also opens into a smaller cylindrical bore 39 at its other end. The bore 39 is in communication with another still smaller bore 41 in the body 36. The bore 41 is in communication with a larger bore 42 and the bore 42 is in communication with a cup-shaped recess 43 formed on the end of the body 36 opposite the end at which the recess 38 is formed.

A valve member or holder 46 is disposed within the large bore 37 and is provided with an annular shoulder 47 which is seated against the bottom of the recess 38. The valve member 46 is also provided with a radially extending flange 48 that is of substantially the same diameter as the recess and which is engaged by a snap ring 49 seated within the recess 51 provided in the body 36 to retain the valve member 46 within the body 36.

The valve member 46 is provided with a bore 52 extending longitudinally thereof intermediate the ends of the same. The bore 52 at one end opens into a fiat-sided circular recess 53 and at the other end opens into a larger bore 54. The innermost end of the valve member 46 is provided with an inclined annular valve seat 56. A plunger 57 is slidably mounted in the bore 52 and is adapted to be moved between open and closed positions with respect to the valve seat 56. Suitable sealing means such as an O-ring 58 is carried by the plunger 57 in an annular recess 59 formed between a radiall extending collar 61 and a shoulder 62 formed as an integral part of the plunger 57. Sealing means is disposed between the plunger and the side wall forming the bore 52 and consists of an O- ring 63 disposed in an annular recess 64 provided on the plunger 57. Sealing means is also disposed between the valve member 46 and the side wall forming the bore 37 and consists of an O-ring 65 mounted in an annular recess 66 in the valve member 46. Means is provided for yieldably urging the plunger toward a closed position and consists of a coil spring 67 having one end engaging a cylindrical boss 68 provided as an integral part of the plunger 57.

The other end of the spring 67 engages a cylindrical boss 69 forming an integral part of a second plunger valve 71. The plunger valve 71 has a valve stem 72 slidably mounted in the bore 41 and is movable between open and closed positions with respect to an annular inclined valve seat 73 formed in the body 36 adjacent the outer end of the bore 39. Suitable sealing means is provided for the plunger valve 71 and consists of an O-ring 74 adapted to engage the seat 73 and which is carried in an annular recess 76 formed between a radially extending collar 77 and a shoulder 78 forming an integral part of the plunger valve 71.

Suitable sealing means is provided for forming a seal about the valve stem 72 and consists of an O-ring 81 mounted within the bore 42 and encircling the valve stem 72. It also includes a washer 82 which is held in place by snap ring 83. The outer end of the valve stem 72 is secured to the central portion of a resilient diaphragm 86. The outer annular margin of the diaphragm 86 is clamped in the recess 43 between the body 36 and a cap 87 which is threaded into the body. It can be seen that separate chambers 88 and 89 are formed on opposite sides of the diaphragm. The chamber 88 is vented to the atmosphere through a small passage 91 provided in the body 36. A gas under positive pressure is adapted to be supplied to the chamber 89 through a nipple 92 threaded into the cap 87. A cap screw 93 serves to close another opening provided in the cap 87 and which is not used. The bore 39 is in communication with and opens into a passage 96 in the body 36. The passage 96 opens into a bore 97 in the body 36. The bore 97 is also in communication with another passage 98 provided in the body 36 and which opens into another bore 99 provided in the bod 36 (see FIGURE 3). A nipple 101 is threaded into the bore 99 whereas a manually controlled flow rate valve 102 is mounted in the bore 97.

The valve 102 is of a conventional type and, as well known to those skilled in the art, consists of a valve body 103 which is threaded into the bore 97. The body is provided with an annular recess 104 which carries an O-ring 106 which forms a sealing engagement with the body 36 and which is in registration with the passage 96. The body is also provided with a passage 107 which is adapted to be opened and closed by a needle valve 108 threaded into the valve body 103. A knob 109 is mounted on the needle valve 108 and is provided for adjusting the needle valve axially of the valve body 103 to control the size of the opening through which gases can pass into a chamber 111 provided in the valve body. A small passage 112 in the valve body 103 establishes communication between the chamber 111 and the passage 98 provided in the body 36.

Mean is provided for shifting the plunger valve 57 to an open position and consists of a toggle member 116 having a flat sided cylindrical member 117 with a handle 118 formed thereon. A sealing ring 119 is mounted over the handle 118 and is held in place by a cap 121 threaded onto the outer end of the valve member 46. The cap 121 is provided with a centrally disposed opening 122 through which the handle 118 extends. The cylindrical member 117 is formed with an arcuate recess 123 and is adapted to accommodate a ball 124 as shown in FIGURES 2 and 4. The ball 124 is of substantially the same diameter as the outer end of the plunger 57 and is adapted to be moved into the bore 52 by movement of the toggle member 116 to shift the plunger to an open position and to retain the same in the open position. The toggle member 116 is shaped in such a manner that the plunger 57 can be held in either an open position or a closed position with respect to the seat 56.

Means is provided for supplying gas under pressure to the chamber formed within the bore 37 and Consists f a threaded bore 126 in which a threaded nipple 127 is mounted. A nut 128 is threaded onto the nipple 127 and is adapted to make a connection with a suitable source of pressure such as the source of pressure 22 indicated in FIGURE 1. The bore 126 is in communication with a passage 129 which opens into the bore 37. Means is also provided for removing gases from the chamber formed by the bore 37 and consists of a passage 131 which is in communication with a bore 132 provided in the body 36. A fitting 133 is threaded into the bore and is adapted to be directly connected to the inlet 12 of the controller 11 shown in FIGURE 1.

The exhalation value consists of a central body 136 which has a double throated venturi-like passage 137 extending longitudinally therethrough. In other words, there is a venturi-like passage provided at each end of the body 136. The body 136 is provided with recessed cylindrical surfaces 138 and 139 on opposite ends. An annular recess 141 is formed in each of the cylindrical surfaces and carries an O-ring 142. A positive jet subassembly 144 is mounted on one end of the central body 136 and a negative jet subassernbly 146 is mounted on the other end of the central body 136. The positive jet subassembly 144 consists of a tubular member 147 which is provided with a cylindrical bore 148 that is adapted to snugly fit over the cylindrical surface 138 and to be retained thereon by the O-ring 142 as shown. The bore 148 serves as a passage which is axially aligned with the venturi-like passage 137 in the body 136. The outer end of the tubular member 147 is provided with an inclined raised shoulder 149 which is adapted to grip a tube if one is connected thereto.

A nozzle 151 is mounted in the tubular member 147 and is centrally disposed within the bore 148 so that when the tubular member 147 is mounted on the central body 136, the nozzle is in axial alignment with one end of the venturi-like passage 137 in the central body 136. Means is provided for supplying air to the nozzle 151 and consists of a pipe 152 which is provided with a portion 152a which extends through the side wall of the tubular member in a radial direction. A portion 15% extends at right angles to the portion 152a and is provided with a nipple portion 1520.

A negative jet subassembly 146 is constructed in a manner similar to the positive jet subassembly 144 and consists of a tubular member 156 which is provided with bores 157, 158 and 159 communicating with each other and each having difierent diameters. The bore 157 is of such size that it can readily fit over the surface 139 provided on the other end of the body 136 and be engaged by the O-ring 142 to hold the negative jet subassembly 146 on the central body 136. The bore 158 serves as a passage which is in alignment with the passage 137 in the body 136.

A nozzle 161 is disposed within the bore 158 of the tubular member and faces the other throat of the venturilike passage 137 and is axially aligned therewith as shown in FIGURE 5. Means is provided for supplying gas under pressure to the nozzle 161 and consists of a pipe 162 which is provided with a portion 16241 which extends radially through the one wall of the tubular member 156 and is secured to the wall of the tubular member. The pipe is also provided with a portion 162!) which extends at right angles to the portion 162a and a nipple portion 1620 which forms a continuation of the portion 16212. The tubular member is provided with an inclined raised shoulder which is adapted to engage any flexible tube which is secured thereto.

As shown in the drawings, the nipple 101 of the control cartridge 21 is connected to one end of a tube 166 and the other end of the tube 1'66 is connected to the pipe 152. The nipple 92 of the control cartridge 21 is connected by a tube 167 to a T-shaped fitting 168 which is mounted in inlet 31 of the nebulizer 24. The T-shaped fitting is also connected by a tube 169 to the positive pressure outlet 16 of the controller 11. The negative pressure outlet 17 of the controller 11 is connected by a tube 171 to the pipe 162. The tubular member 156 of the exhalation valve 23 is connected to one branch of a bifurcated or Y type patient adapter 26 by tube 172. The outlet 29 of the nebulizer is provided with a fitting 173. The fitting 173 is connected by a tube 174 to the patient adapter 26. The patient adapter 26 can be of any suitable type but, as shown in the drawing, can be a tracheotomy fitting.

Operation and use of the respirator may now be briefly described as follows. Let it be assumed that it is desired to place the respirator in operation. This is accomplished by shifting the toggle member 116 into a position so that it urges the ball 124 into the bore 52 to urge the plunger 57 to the right as viewed in FIGURE 2 to move the plunger to an open position with respect to the valve seat 56 against the force of the spring 67. Gas under pressure from the source 22 passes through the fitting 127 through the passage 129 into the bore 37. The gas then passes into the bore 54 through the passage 131 through the fitting 133 to the inlet 12 of the controller 11.

Assuming that the controller 11 is in the inspiration phase, a gas under positive pressure is produced through the main outlet 13 and passes through the nebulizer 24 through the outlet 29 of the nebulizer and to the bifurcated patient adapter 26 to the airway of the patient. At the same time that gases are being supplied under a positive pressure through the outlet 13, gas is also being supplied under a higher positive pressure through the positive pressure outlet 16 to the T-shaped fitting 168. Part of this positive pressure is supplied to the nebulizer 24 to nebulize the bronchial dilator or any other substance carried by the nebulizer so that droplets of the same enter into the main stream of gas passing from the outlet 29 to the patient adapter 26. At this same time, gas under positive pressure is also supplied to the nipple 92 of the control cartridge 21 to supply positive pressure to the chamber 89 and to shift the diaphragm 8'6 to the left as viewed in FIGURE 2 to also move the plunger 72 to an open position with respect to the seat 73. Gas under pressure, therefore, passes into the bore 39 through the passage 96 and then through the flow rate control valve 102 at a rate determined by the valve 102 through the passage 98 to the nipple 191 and to the nozzle 151 which supplies a jet of air to one end of the venturi-like passage 137. The jet of air passing through the passage 137 causes additional air molecules to be entrained and urged into the passage 137 from the atmosphere and to thus supply additional gas under pressure to the patient adapter 26. The valve 102 is adjusted so that the rate of flow of gas from the nozzle 151 is sufficient to effectively seal the left-hand end of the exhalation valve 23, as viewed in FIGURE 1, to prevent gas being supplied to the patient from being exhausted to the atmosphere. It also has an additional function to aspirate atmospheric air into the right-hand side of the exhalation valve 23 and to deliver additional gas under pressure to the patient adapter during the inspiratory phase of the respirator. Thus, during the inspiratory phase, the jet passing from the nozzle 151 in combination With the venturi-like passage 137 can be considered to create a valve closure to the rear of the nozzle 151 because of the molecular barrier which is set up by this venturi action. This barrier can be stationary or it can move towards the patient at rates depending upon the adjustment of the flow valve 102 and the resistances which may be encountered in the patient due to obstructions in the air ways of the lungs and changes in lung compliance as well as the resistances in the mechanical circuit to the patient adapter.

As soon as the inspiratory phase has been completed and is sensed by the controller 11, the controller switches to the negative or exhalation phase. When this occurs, positive pressure is no longer supplied through the outlet 16 and, therefore, the plunger 72 is returned to its closed position by action of the spring 67. This stops the flow of gas from the nozzle 151. At the same time, a negative pressure flow is developed in the outlet 17 of the controller and is supplied to the nozzle 161 to produce a jet of air passing through the venturi-like passage 137 in an opposite direction to create a negative pressure gradient which aspirates the gases in the airway of the patient and discharges the same to the atmosphere through the tubular member 147. Thus, it can be seen that during the expiratory or exhalation phase, the exhaled gases proceed through the exhalation valve 23 and are discharged to the atmosphere.

As soon as the expiratory phase has been completed, the controller 11 is cycled into the inspiratory phase and the same sequence of operations takes place.

From the foregoing, it can be seen that the jet of gases passing through the nozzle 151 into the venturi-like passage 137 acts like a pneumatic clutch. If changes in resistance and changes in obstructions are met, the gas flow is automatically converted from pressure into gas flow. In other words, when airway resistance of the patient increases, flow is converted into pressure because of this venturi-like action and when the resistance is diminished, the same venturi-like action converts the pressure into flow of the gases. In other words, the kinetic energy of the gas flow is converted to higher pressures to overcome the resistances and this same kinetic energy is transformed back into flow to increase the gas flow to the patient to improve the ventilation. During the inspiratory phase, the molecular barrier Which is created on the left-hand side of the exhalation valve 23, as viewed in FIGURE 1, also can be considered as a type of relief valve which prevents premature peak inspiratory pressure from being developed while obstructions are being overcome.

In view of the fact that the exhalation valve does not contain any moving parts, it can be rapidly shifted from the inhalation phase to the exhalation phase. As hereinbefore described, the exhalation valve merely makes it possible to move a molecular barrier towards or away from the patient to accomplish all the functions of a conventional exhalation valve with moving parts which have inertia.

By utilizing an exhalation valve of this type, rapid cycling between the exhalation and inhalation phases can be accomplished. In view of this fact, the respirator is particularly adapted for giving mechanical assistance to infants where rapid breathing rates are required.

The respirator shown in the drawings has additional advantages in view of the fact that two separate flow passages are provided to the patient adapter 26. One passes through the main controller 11 Whereas the other passes through the exhalation valve 23. The control cartridge 21 includes a flow rate control valve 102 for adjusting the rate of fiow through the exhalation valve and the controller 11 as described in United States Letters Patent No. 3,191,596 also includes a flow rate control valve for adjusting the rate of flow of gas through the other main outlet passage 13 to the patient adapter 26 through the nebulizer 24. The flow rate to the patient adapter can be increased merely by increasing the amount of gas passing through the nozzle 151. The length of the inspiratory phase can be controlled by the flow rate valve of the controller 11. Thus, by adjusting the rate of flow of gases through the controller 11, the rate of flow of the main stream gases through the nebulizer 24 can be readily controlled and set at a desired value with any additional gases required for the patient being supplied through the exhalation valve 23 by operation of the manually operated flow rate valve 102.

This parallel arterial circuit in the present respirator can also be utilized for operating a spirometer and any other accessory items. Because of the parallel circuit, this can be done without disturbing the flow rate pattern to the patient which is controlled by the controller 11. When increased nebulization is required, additional flow can be caused to pass through the nebulizer 24 while decreasing the flow through the exhalation valve 23.

The control cartridge 21 also provides additional features for the respirator. The toggle 116 makes it possible to turn the respirator on and off with a single control. Thus, once a respiratory pattern has been set up for the controller 11, the entire respirator can be turned on and off with the toggle 116. The control cartridge 21 also makes possible the parallel booster passage hereinbefore described which is phased with the controller 11 and only works during the inspiratory phase.

It is apparent from the foregoing that there has been provided a new and improved respirator which has many advantageous features which is particularly adapted for use in the infant resuscitation field. The particularly novel pneumatically controlled exhalation valve utilized in the respirator is particularly novel in that it is very simple and does not require any mechanical movements. If desired, the exhalation valve can be utilized with only a positive jet subassembly. The exhalation valve is also advantageous in that it can be made relatively small and light in weight and, therefore, would be particularly advantageous for use on tracheotomized patients. The exhalation valve can also be used in a Q circle.

We claim:

1. In a respirator having an inhalation phase and an exhalation phase in its operative cycle, a controller having an inlet adapted to be connected to a source of gas under pressure, said controller having an outlet adapted to be connected to the airway of the patient, said controller including means permitting gas under pressure t9 flow from the outlet during the inhalation phase and preventing the fiow of gas under pressure from the outlet during the exhalation phase, an exhalation valve, said exhalation valve including a valve body having a venturilike passage therein, means connected to one end of the body and adapted for directly connecting one end of the passage to the airway of the patient, a tubular member mounted on the other end of the body having a passage extending therethrough in axial alignment with the passage in the body, a nozzle mounted within said tubular member and facing the passage in said body, the other end of said passage being open directly to the atmosphere through the passage in said tubular member, and means including a control cartridge connected to said nozzle and adapted for connection to a source of gas under pressure for supplying gas under pressure to the nozzle during the inhalation phase to cause a jet of gas to travel from the nozzle down the passage in a direction toward said one end of the passage to cause molecules of gas from the atmosphere to be entrained and to pass through said passage.

2. A respirator as in claim 1 together with means for adjusting the rate of flow through the nozzle.

3. A respirator as in claim 1 together with means connecting the control cartridge to the controller so that the control cartridge operates in phase with the controller.

4. A respirator as in claim 1 wherein said exhalation valve includes a second nozzle mounted on the body and facing oppositely of said first named nozzle and means for supplying gas under pressure to said second named nozzle during the exhalation phase of the respirator.

5. In a respirator having an inhalation phase and an exhalation phase in its operative cycle, a controller having an inlet adapted to be connected to a source of gas under pressure and an outlet adapted to be connected to the airway of the patient, said controller including means for controlling the flow of gas through the controller so that gas is only supplied to the outlet during the inhalation phase of the controller, said controller also having a positive pressure outlet, a control cartridge, said control cartridge having an inlet adapted to be connected to the source of gas under pressure, an outlet, and diaphragm operated valve means movable between open and closed positions for controlling the flow of gas from the inlet to the outlet of the control cartridge, means for supplying gas from the positive pressure outlet of the controller to said diaphragm operated means to move said diaphragm operated valve means to an open position to permit gas to flow from the inlet to the outlet of the control cartridge, an exhalation valve comprising a valve body having a venturi-like passage therein, means adapted for connecting one end of the passage to the airway of the patient, a nozzle mounted on the body adjacent to the other end of the passage and facing said one end, said other end of the venturi-like passage being open to the atmosphere, and means connecting the outlet of the control cartridge to the nozzle to supply gas under pressure to the nozzle to produce a jet of gas entering the venturi-like passage and entraining atmospheric air for delivery to the airway of the patient.

6. A respirator as in claim 5 together with means mounted on the cartridge for controlling the rate of flow of gas from the inlet to the outlet of the control cartridge.

7. A respirator as in claim 5 wherein said controller includes a negative pressure outlet, and wherein said exhalation valve includes an additional nozzle mounted on the valve body and facing oppositely of said first named nozzle and means connecting the negative pressure outlet of the controller to the additional nozzle to supply air under pressure to the nozzle during the exhalation phase of the respirator.

8. In a respirator having an inhalation phase and an exhalation phase in its operative cycle, a controller having an inlet and an outlet, a control cartridge having an inlet adapted to be connected to a source of gas under pressure, said control cartridge also having an outlet, means connecting the outlet of the control cartridge to the inlet of the controller, said control cartridge including manually operated valve means for controlling the flow of gas under pressure from the inlet to the outlet, means for connecting the outlet of the controller to the airway of the patient, said controller having a positive pressure outlet, the control cartridge having an additional outlet in communication with the inlet of the control cartridge, diaphragm operated valve means for controlling the flow of gas from the inlet to the additional outlet of the control cartridge, means connecting the positive pressure outlet of the controller to the diaphragm operated valve means, said controller including means for supplying gas under pressure to the positive pressure outlet of the controller only during the inhalation phase, whereby said diaphragm operated valve means is moved to an open position during the inhalation phase and permits gas under pressure to flow through the additional outlet of the control cartridge, an exhalation valve comprising a valve body having a venturi-like passage therein, a nozzle mounted on the body and facing one end of the venturi-like passage, the other end of the venturi-like passage being open to the atmosphere, means adapted to connect the one end of the venturi-like passage to the airway of the patient, and means connecting the additional outlet of the control cartridge to the nozzle of the exhalation valve for supplying a jet of gas to the venturilike passage to cause additional air to be entrained for delivery to the airway of the patient.

9. A respirator as in claim 8 wherein said control cartridge includes a flow rate valve for adjusting the rate of flow from the inlet to the additional outlet.

10. A respirator as in claim 8 wherein said controller includes a negative pressure outlet in which air under pressure is supplied during the exhalation phase of the respirator, an additional nozzle mounted on said valve body and facing said other end of said passage and means connecting the negative pressure outlet to said additional nozzle.

11. In an exhalation valve for use in a respirator of the type having an inhalation phase and an exhalation phase in its operative cycle and having a patient adapter adapted to be connected to the airway of a patient, a

valve body having a venturi-like passage therein, means mounted on one end of the body adapted to directly connect one end of the passage to said patient adapter, a tubular member mounted on the other end of said body and having a passage extending therethrough and in axial alignment with the passage in the body, a nozzle mounted within said tubular member and facing the passage in said body, the other end of said passage being open directly to the atmosphere through the passage in the tubular member, said nozzle being adapted for receiving gas under pressure during the inhalation phase of the respirator to cause a jet of gas to travel from the nozzle down the passage in the body to cause molecules of air from the atmosphere to be entrained and to pass through said passage in said body, an additional nozzle mounted on said body and facing oppositely of said first named nozzle, and means for supplying gas under pressure to said additional nozzle during the exhalation phase of the respirator.

12. In an exhalation valve, a valve body having a venturi-like passage therein, a tubular member removably mounted on each end of the body and having a passage extending therethrough axially aligned with the passage in said body, a nozzle carried by each of the tubular members and facing the end of the passage in said body on which the tubular member is mounted.

13. An exhalation valve as in claim 12 wherein piping is connected to each of said nozzles and wherein said piping extends through the side walls of the tubular members.

References Cited UNITED STATES PATENTS 3,373,688 3/1968 Howard 23092 XR FOREIGN PATENTS 24,966 3/ 1963 Germany.

309,595 12/1918 Germany.

RICHARD A. GAUDET, Primary Examiner K. L. HOWELL, Assistant Examiner US. Cl. X.R. 

